Publicação

Tumour-infiltrating NK cells and γδ T-cells for cellular immunotherapy

Detalhes bibliográficos
Resumo:	The frequent downregulation or complete loss of major histocompatibility complex (MHC) expression by tumour cells often compromises patients’ response to standard cancer treatments or αβ T-cell-based therapies. Thus, NK cell and ɣδ T-cell-based cancer immunotherapies emerged as complementary treatments. Both immunotherapies have been successfully used to target haematological malignancies but their effectiveness in patients with solid tumours has limited their therapeutic application. Most NK cell and ɣδ T-cell-based immunotherapies use cells isolated and expanded from peripheral blood mononuclear cells, which may result in a cellular product with low homing capacity and/or anti-tumour reactivity. We aimed therefore to explore the feasibility of isolating and expanding tumour-reactive NK cells or ɣδ T-cells directly from the tumour tissue of patients with cancer. Different expansion protocols using cytokine combinations of IL-2, IL-15, IL-7 or IL-1β along with molecularly defined targets for ɣδ T-cells were tested for their capacity to preferentially isolate and expand ɣδ T-cells from patients’ tumour, while IL-2, IL-15 and stimulation with the K-562 cell line was used for NK cell isolation and expansion. The protocols’ efficiency was assessed by evaluating the total cell number, cell viability and NK cells or ɣδ T-cells’ frequency. Cells’ functional capacity was determined by their ability to produce IFN-ɣ in response to autologous tumour cells and/or allogeneic cancer cell lines. We demonstrate that NK cells and ɣδ T-cells can be directly isolated from patients’ tumour tissue and are able to recognize autologous tumour cells, producing IFN-ɣ. Tumour-infiltrating ɣδ T-cells revealed inclusive to use their T-cell receptor to target autologous tumour cells in vitro. In summary, our data provide the first evidence that tumour-infiltrating NK cells and γδ T-cells can be expanded from cancer lesions and may be used in cancer immunotherapy for patients with solid tumours.
Autores principais:	Condeço, Ana Carolina Grais
Assunto:	Células T γδ Células NK Tecido tumoral Células tumorais MHC negativas Recetor recetor das células T γδ Reatividade anti-tumoral Yδ T-cells NK cells Tumour tissue MHC negative tumour cells Yδ T-cell receptor Antitumour reactivity
Ano:	2021
País:	Portugal
Tipo de documento:	dissertação de mestrado
Tipo de acesso:	acesso aberto
Instituição associada:	Universidade Nova de Lisboa
Idioma:	inglês
Origem:	Repositório Institucional da UNL

Descrição
Resumo:	The frequent downregulation or complete loss of major histocompatibility complex (MHC) expression by tumour cells often compromises patients’ response to standard cancer treatments or αβ T-cell-based therapies. Thus, NK cell and ɣδ T-cell-based cancer immunotherapies emerged as complementary treatments. Both immunotherapies have been successfully used to target haematological malignancies but their effectiveness in patients with solid tumours has limited their therapeutic application. Most NK cell and ɣδ T-cell-based immunotherapies use cells isolated and expanded from peripheral blood mononuclear cells, which may result in a cellular product with low homing capacity and/or anti-tumour reactivity. We aimed therefore to explore the feasibility of isolating and expanding tumour-reactive NK cells or ɣδ T-cells directly from the tumour tissue of patients with cancer. Different expansion protocols using cytokine combinations of IL-2, IL-15, IL-7 or IL-1β along with molecularly defined targets for ɣδ T-cells were tested for their capacity to preferentially isolate and expand ɣδ T-cells from patients’ tumour, while IL-2, IL-15 and stimulation with the K-562 cell line was used for NK cell isolation and expansion. The protocols’ efficiency was assessed by evaluating the total cell number, cell viability and NK cells or ɣδ T-cells’ frequency. Cells’ functional capacity was determined by their ability to produce IFN-ɣ in response to autologous tumour cells and/or allogeneic cancer cell lines. We demonstrate that NK cells and ɣδ T-cells can be directly isolated from patients’ tumour tissue and are able to recognize autologous tumour cells, producing IFN-ɣ. Tumour-infiltrating ɣδ T-cells revealed inclusive to use their T-cell receptor to target autologous tumour cells in vitro. In summary, our data provide the first evidence that tumour-infiltrating NK cells and γδ T-cells can be expanded from cancer lesions and may be used in cancer immunotherapy for patients with solid tumours.